Adaptive Randomization of Veliparib–Carboplatin Treatment in Breast Cancer

Rugo, Hope S.; Olopade, Olufunmilayo I.; DeMichele, Angela; Yau, Christina; Veer, Laura J. van ’t; Buxton, Meredith; Hogarth, Michael; Hylton, Nola M.; Paoloni, Melissa; Perlmutter, Jane; Symmans, W. Fraser; Yee, Douglas; Chien, Amy Jo; Wallace, Anne M.; Kaplan, Henry G.; Boughey, Judy C.; Haddad, Tufia C.; Albain, Kathy S.; Liu, Minetta C.; Isaacs, Claudine; Khan, Qamar J.; Lang, Julie E.; Viscusi, Rebecca K.; Pusztai, Lajos; Moulder, Stacy L.; Chui, Stephen Y.; Kemmer, Kathleen; Elias, Anthony; Edmiston, Kirsten K.; Euhus, David M.; Haley, Barbara; Nanda, Rita; Northfelt, Donald W.; Tripathy, Debasish; Wood, William C.; Ewing, Cheryl A.; Schwab, Richard B.; Lyandres, Julia; Davis, Sarah E.; Hirst, Gillian L.; Sanil, Ashish; Berry, Donald A.; Esserman, Laura J.

doi:10.1056/nejmoa1513749

Cited by 490 publications

(348 citation statements)

References 23 publications

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“…These trials may incorporate common control arms for meaningful endpoints, a fluid infrastructure for adding or dropping experimental arms, and an ability to use data as it is available during the trial to alter decision-making in a prespecified manner. The most notable example is I-SPY 2 in breast cancer (3,16,17). Using such a design to evaluate new therapies for GBM requires some changes but the overall concepts and goals may still be applied (18).…”

Section: Background and Rationalementioning

confidence: 99%

Adaptive Global Innovative Learning Environment for Glioblastoma: GBM AGILE

Alexander

Berger

et al. 2018

Clinical Cancer Research

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175

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Glioblastoma (GBM) is a deadly disease with few effective therapies. Although much has been learned about the molecular characteristics of the disease, this knowledge has not been translated into clinical improvements for patients. At the same time, many new therapies are being developed. Many of these therapies have potential biomarkers to identify responders. The result is an enormous amount of testable clinical questions that must be answered efficiently. The GBM Adaptive Global Innovative Learning Environment (GBM AGILE) is a novel, multi-arm, platform trial designed to address these challenges. It is the result of the collective work of over 130 oncologists, statisticians, pathologists, neurosurgeons, imagers, and translational and basic scientists from around the world. GBM AGILE is composed of two stages.The first stage is a Bayesian adaptively randomized screening stage to identify effective therapies based on impact on overall survival compared with a common control. This stage also finds the population in which the therapy shows the most promise based on clinical indication and biomarker status. Highly effective therapies transition in an inferentially seamless manner in the identified population to a second confirmatory stage. The second stage uses fixed randomization to confirm the findings from the first stage to support registration. Therapeutic arms with biomarkers may be added to the trial over time, while others complete testing. The design of GBM AGILE enables rapid clinical testing of new therapies and biomarkers to speed highly effective therapies to clinical practice.

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Section: Background and Rationalementioning

confidence: 99%

Adaptive Global Innovative Learning Environment for Glioblastoma: GBM AGILE

Alexander

Berger

et al. 2018

Clinical Cancer Research

Self Cite

175

121

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“…velparib in combination with carboplatin was recently found to have a pCR of 51% in patients with TNBC in the adaptive randomization trial I-SPY2, supporting further phase III study. 57 The OlympiA trial of one year of olaparib in the adjuvant setting for patients with germline BRCA mutations is also ongoing (NCT02032823).…”

Section: Antibody Drug Conjugatesmentioning

confidence: 99%

Triple Negative Breast Cancer—Review of Current and Emerging Therapeutic Strategies

Ballinger

Kremer

Miller

2016

Oncology &Amp; Hematology Review (US)

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T riple negative breast cancer (TNBC) is associated with a poor prognosis compared to other types of breast cancer. The classification of 'triple negative' is not one homogenous tumor type, but rather is made up of multiple molecularly and biologically diverse tumor subtypes. At present, no approved targeted therapy exists and the standard remains cytotoxic chemotherapy. The identification of TNBC subtypes has provided a basis for identifying possible targeted therapeutic options. In addition, the recognition that some TNBCs share characteristics similar to tumors arising in patients with germline BRCA mutations has led to consideration of DNA damaging agents as a potential treatment option. Multiple investigational approaches are also underway, including immune checkpoint inhibition, poly (ADP-ribose) polymerase inhibition, and androgen receptor blockage. The limited options available for systemic treatment of TNBC will hopefully expand as more is learned about the complex biology and molecular targets of this group of breast cancers. This review will discuss the biology of TNBC, current treatment options, and promising experimental strategies. KeywordsTriple negative, breast cancer, therapeutics 1 It is more common in African American women, younger women, and those with a germline BRCA1 mutation. Due to lack of ER, PR, and HER2 and the significant heterogeneity among TNBC, no approved targeted therapies exist and standard treatment remains cytotoxic chemotherapy. While response rates to chemotherapy in early stage disease are high, patients remain at high risk for relapse and prognosis remains inferior to other types of breast cancer. Subtyping and molecular characteristicsIn a seminal paper by Perou et al., gene expression profiling was used to categorize breast cancers into five molecular subtypes. The basal-like type is characterized by lack of ER, PR, and HER2 expression, expression of cytokeratins and EGFR, and a clinically more aggressive phenotype.2 This subtype overlaps with TNBC but the terms are not synonymous; in fact, about one fourth of TNBCs are not basal-like by gene expression, and some non-TNBCs are basal-like by molecular profiling (see Figure 1). 3,4 As more is discovered about the biology of TNBC, it has become clear that this category of breast cancer is not one homogeneous tumor type, but rather is made up of a group of molecularly diverse tumor subtypes. These subtypes have varying gene expression profiles, clinical characteristics, and responses to treatment. In an effort to translate the heterogeneity of TNBC into rational clinical design, Lehmann and colleagues further characterized TNBC into six distinct subtypes based on molecular profiles, each with unique drivers and clinical phenotypes. These subtypes include basal-like 1 (BL1), basal-like 2 (BL2), immunomodulatory (IM), mesenchymal (M), mesenchymal stem-like (MSL), and luminal androgen receptor(LAR).5 Each exhibited different sensitivities to therapeutic agents, both in cell line models and in some retrospective clinical trials...

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“…The overall benefits of treatments targeting cancer driver molecules over traditional cytotoxic chemotherapy are clear; targeted treatments result in greater efficacy and less debilitating or dose-limiting side effects [13][14][15][16][17]. Some of the earliest examples of success in molecularly targeted cancer drug development include tamoxifen and trastuzumab that specifically inhibit the protein products of the estrogen receptor 1 (ESR1) gene (estrogen receptor-alpha) and human epidermal growth factor receptor 2 (ERBB2) gene (HER2), respectively, for the treatment of breast cancer.…”

Section: Molecularly Targeted Treatment Of Cancer and Clinical Genomicsmentioning

confidence: 99%

How the future of clinical cancer diagnostics can contribute to overcoming race-associated cancer disparities

Bollig‐Fischer

2016

Expert Review of Molecular Diagnostics

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Adaptive Randomization of Veliparib–Carboplatin Treatment in Breast Cancer

Cited by 490 publications

References 23 publications

Adaptive Global Innovative Learning Environment for Glioblastoma: GBM AGILE

Adaptive Global Innovative Learning Environment for Glioblastoma: GBM AGILE

Triple Negative Breast Cancer—Review of Current and Emerging Therapeutic Strategies

How the future of clinical cancer diagnostics can contribute to overcoming race-associated cancer disparities

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